REBCO HTS Wire Manufacturing and Continuous Development at SuperPower

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Zhang, Satoshi Yamano, Drew Hazelton, and Toru Fukushima 2018 IAS-HEP

1 Superior performance. Powerful technology. REBCO HTS Wire Manufacturing and Continuous Development at SuperPower Yifei Zhang, Satoshi Yamano, Drew Hazelton, and Toru Fukushima 2018 IAS-HEP Mini-Workshop on High Temperature Superconducting Materials and Magnets The Hong Kong University of Science and Technology January 18, 2018

2 Outline Introduction to SuperPower Inc. REBCO wire and its manufacturing Applications of REBCO wire Performance and quality of REBCO wire Development and challenges Summary 2

Toru Fukushima Product: REBCO 2G HTS wire A subsidiary of

3 Introduction to SuperPower Formed in 2000 Location: Schenectady, New York Number of employees: 30 President & CEO : Dr. Toru Fukushima Product: REBCO 2G HTS wire A subsidiary of Furukawa Electric Co. Ltd. Since 2012 Superior performance. Powerful technology. 3

4 A brief history of SuperPower : The Intermagnetics Years SuperPower formed under IGC (Intermagnetics General Corporation) 2G HTS wire technology research & development Demonstration projects electric power applications : The Philips Years Production scale-up Market exploration Performance improvements, flux pinning enhancement From 2012 onward: The Furukawa Years Steady expansion of production capacity Continuous performance improvements Continuous R&D, customization Processing optimization for quality and yield enhancement 4

5 Furukawa has a long history in LTS Nb-Ti wire with various Cu ratio & filament sizes Low ac loss Nb-Ti wire Al-stabilized Nb-Ti wire High Jc Nb 3 Sn wire High strength Nb 3 Sn wire Al-stabilized Nb-Ti Rutherford cable Nb-Ti Rutherford cable with cored bar Nb-Ti Rutherford cable with high-precision

6 REBCO wire manufacturing at SuperPower Electropolishing IBAD Buffer Deposition MOCVD Electroplating IBAD-MOCVD based technologies 6

7 REBCO wire basic information Item Value Note Composition REBa2Cu3O7-d RE=Rear Earth Width (mm) (1), 2, 3, 4, 6, 12 Substrate Thickness (µm) 30, 50, 100 Hastelloy Ag Thickness (µm) 1~5 Sputtered Cu Thickness (µm) 10~115 total Electroplated Insulation Polyimide tape Wrapped Piece Length (m) 300~500 Joint resistance (nw) <20 Soldered Ic(77K, s.f.) (A/12mm) 300~600 at 1µV/cm sc,0.95 (MPa) ~550 gs dependent ec,0.95 (%) ~0.4 Min Bending D (mm) 5, 11, or 25 Substrate dependent Cross-sectional image of a Cu-plated wire 7

8 Targeted applications of REBCO HTS wires Energy Defense Transportation Industrial Medical Science/ Research Cables FCLs Generators Transformers SMES Fusion Reactors Motors Cables Maglev Motors Induction Heaters Motors Generators Magnetic Separation Bearings MRI Particle Therapy Current Leads HF Magnets NMR Accelerators Neutron and X-ray Scattering Undulators 8

32T hybrid user magnet by NHMFL HTS/LTS hybrid

conductor Wire width 4mm Wire thickness <0.

9 32T hybrid user magnet by NHMFL HTS/LTS hybrid magnet LTS 15T HTS 17T Uniformity 1 cm DSV Total inductance 254 H Stored energy 8.6 MJ Ramp to 32 T 1 hour Cycles 50,000 HTS conductor Wire width 4mm Wire thickness <0.170mm Ic at 17T, 18, 4.2K >256A n-value at 17T, 18, 4.2K >25 Stabilizer RRR >50 Iop 180A 9

total thickness 75µm Cu stabilizer 10µm per side Coil 1: 26 DP, 369MHz,

10 1.3 GHz hybrid NMR by MIT H800 Top=4.2K, Iop=251A 3-nested-coil formation NI DP coils Tape width 6mm Tape total thickness 75µm Cu stabilizer 10µm per side Coil 1: 26 DP, 369MHz, 8.66T Coil 2: 32 DP, 242MHz, 5.68T Coil 3: 36 DP, 189MHz, 4.44T HTS contribution: 61.5% of 30.5T Y. Iwasa 10

11 ARC fusion reactor proposed by MIT (Affordable, Robust and Compact) 9.2 T, 500MW, Q=10 HTS magnets at 9.2T on axis, 23T on coil Much smaller than ITER 1/10 th the volume same gain 5,000 tons 60,000 kam of HTS Demountable joints for maintenance 11

12 Spherical fusion reactor by Tokamak Energy ST25 (HTS) ST40 (LN2 cooled Cu) ST140 (HTS) 12

strong Flexible High level of conductor transposition First commercial sale (CERN) 12 meter CORC

13 REBCO HTS high current cables CORC (Conductor on Round Core) Cable Fabricated by winding multiple wires in a helical way around a small round former High currents and current densities Mechanically strong Flexible High level of conductor transposition First commercial sale (CERN) 12 meter CORC cable (38 tapes) Cable for detector magnets Delivered August 2014 Courtesy of D. van der Laan, ACT LLC 13

Canted-Cosine-Theta magnets wound from CORC wires

CCT insert with 10 T (15 T) LTS CCT outsert

2 K, self-field, 2-3 T in 10 T, high-je CORC wire

14 Canted-Cosine-Theta magnets wound from CORC wires CORC CCT magnet program goals Reach 5 T in CORC CCT insert with 10 T (15 T) LTS CCT outsert Develop the CORC CCT magnet technology in several steps C1: 1 T 4.2 K, self-field, low-je CORC wire C2: 4-5 T 4.2 K, self-field, 2-3 T in 10 T, high-je CORC wire C3: 5 T in 15 T background, advanced CORC wires CCT C1 Courtesy of D. van der Laan, ACT LLC CCT C2-0 14

15 REBCO HTS high current cables Twisted Stacked-Tape Cable (TSTC) Courtesy of M. Takayasu, MIT-PSFC 15

16 REBCO HTS high current cables Twisted Stacked-Tape Cable (TSTC) Conductor Scale-up Courtesy of M. Takayasu, MIT-PSFC 16

17 REBCO HTS high current cables Roebel Cable Fabricated by winding mechanically punctured meandering tapes High current and low AC loss Stacked-tape Cable Source: Two-step cabling 16 tapes per strand, twisted at 32 cm. 20 strands per cable, twisted at 100cm 60kA at 12T Nikolay Bykovsky et al, EUCAS

18 Performance and quality of REBCO wire I c (B, T, ) Field dependence Angular dependence Minimum I c ( ) Engineering current density, Je Uniformity along length (piece length) and consistency Electromechanical properties (stress and strain limits) Critical stress and strain Irreversible stress and strain Fatigue (in various stress states) Overcurrent stability Joint Geometry Resistance (resistivity) Electromechanical strength (stress and strain limits) AC losses Insulation 18

19 I c (A/4mm-w) In-field performance K, B//c B (Tesla) 19

optimized for various applications High-temperature low-field Intermediate-temperature

20 In-field performance tailored structure Effect of Zr doping level on Ic(BT ) 7.5%Zr, 15%Zr, or higher Field, temperature and angular dependence Wire classification optimized for various applications High-temperature low-field Intermediate-temperature intermediate-field Low-temperature high-field Cross-section, TEM, 7.5%Zr Cross-section, TEM, 15%Zr 20

21 In-field performance correlation Earlier work at University of Houston suggested There is no correlation between Ic(30K, 3T//c) and Ic(77K, 0T) There is a fairly good correlation between Ic(30K, 3T//c) and Ic(77K, 3T//c) V. Selvamanickam, et al, SUST, 27(2014)

22 Ic(4.2K, 8T) (A/4mm) Ic (4.2K, 5T) (A/4mm) Ic (4.2K, 17T) (A/4mm) In-field performance correlation B//c Ic (77K, 0T) (A/4mm) Our recent data suggested There is a loosely inverse correlation between Ic(4.2K, 5T//c) and Ic(77K, 0T) There is a fairly good correlation between Ic(4.2K, 17T//c) and Ic(4.2K, 5T//c) There is a fairly good correlation between Ic(4.2K, 8T//c) and Ic(30K, 2T//c) B//c Ic (4.2K, 5T) (A/4mm) Ic(30K, 2T) (A/4mm) 22

23 Ic 1.5T) Angular dependence and anisotropy Biaxially textured REBCO film is essentially highly anisotropic material Ic is dependent on magnetic field orientation The anisotropy is determined by the pinning landscape C-axis oriented BZO nano columns effectively enhance the pinning when B//c, therefore change the anisotropy The pinning effect from BZO is temperature and field dependent Measured 90 Fitting Angle (deg.) Where D. K. Hilton, et al, SUST, 28(2015)

24 I c uniformity along length magnetic measurement Position (cm)(on a 4 mm wide wire) Non-contact measurement High spacial resolution, high speed, and reel-to-reel Monitoring I c at multiple production points after MOCVD Capable of quantitative 2D uniformity inspection 24

25 Ic uniformity along length transport measurement Ic (77K, s.f.) >160A, Piece length ~ 780m 25

26 Ic (A/4mm-w) Consistent in-field performance : made with M3 : made with M B//c (T) 4.2K 26

Higher J e (engineering current density) wire with thinner substrate Thinner substrates (30mm or thinner) lead to higher Je without compromising the functionality of

27 Higher J e (engineering current density) wire with thinner substrate Thinner substrates (30mm or thinner) lead to higher Je without compromising the functionality of stabilizer that needs to be of certain thickness Higher J e and the flexibility of thinner wire facilitates fabrication of high current cables A. Sundaram, et al, SUST, 29(2016)

28 Higher J e (engineering current density) wire with thinner substrate LBC3 HTS insert in 31T resistive magnet reached 45.46T Courtesy of D. Abraimov, NHMFL Hahn, et al EUCAS

Mechanical and electromechanical properties and testing Axial tensile test at room temperature or

stress and irreversible stress (strain) Torsion-tension test at 77K (with I c ) Measurement of

Measurement of critical compressive stress Bending test at 77K (with I c ) Measurement of minimum

temperature Pin-pull (c-axis tensile) test: at room temperature Anvil (c-axis tensile) test: at

29 Mechanical and electromechanical properties and testing Axial tensile test at room temperature or at 77K (with I c ) Measurement of elastic modulus and yield stress Determination of critical stress and irreversible stress (strain) Torsion-tension test at 77K (with I c ) Measurement of critical tensile stress under twist Transverse (c-axis) compressive test at 77K (with I c ) Measurement of critical compressive stress Bending test at 77K (with I c ) Measurement of minimum bending diameter Measurement of delamination strength various testing methods Peel test: at room temperature Pin-pull (c-axis tensile) test: at room temperature Anvil (c-axis tensile) test: at room temperature or at 77K (with I c ) Uniaxial tension Transverse Compression Torsion + tension Peel Test 29

30 Effect of stabilizer thickness ratio on critical stress under uniaxial tension 77 K g s = t (Ag+Cu) /t total 30

31 Continuous development and engineering Wire on thinner substrates Higher engineering current density and enhanced mechanical flexibility For fabrication of high current cables and high-field magnets Different REBCO formula tailored for various operating conditions Intermediate-temperature (30-50K) and intermediate-field (2-4T) applications Low-temperature (4.2K) high-field (>10T) applications Bonded wires Enhanced performance and specific functionality Wire filamentization Reduction of AC loss Mitigation of screening effect Alternative insulation Thinner and more uniform Current Leads AgAu instead of pure Ag Solder Coating Facilitate cabling 31

32 Summary In a longer term REBCO HTS wire holds a great promise for electric power, transportation and medical applications (high reliability required) REBCO HTS wire has the advantages over other superconducting wires and its Ic level is high enough for many high-field magnet applications Different types of high-current /low-ac-loss cables are being developed, which will facilitate the adoption of REBCO HTS wire for magnet applications Continuous development efforts are focused on Further reduction in wire price and increase in wire production capacity Further improvements in wire performance and quality Technology advancements in AC loss reduction, joint and termination fabrication, insulation, quench detection/protection 32

2G HTS Wire for Demanding Applications and Continuous Improvement Plans

superior performance. powerful technology. 2G HTS Wire for Demanding Applications and Continuous Improvement Plans DW Hazelton Tuesday, September 17, 2013 EUCAS-2013, Genova, Italy SuperPower Inc. is a